CN215799167U - Product cutting production line - Google Patents

Abstract

The utility model discloses a product cutting production line which comprises a feeding mechanism, a first cutting machine, a translation turnover mechanism, a second cutting machine and a carrying mechanism which are sequentially arranged along the product conveying direction. The carrying mechanism comprises at least one carrying assembly for carrying products, the carrying assembly is arranged on two parallel supports arranged along the product conveying direction in a sliding mode through an X-axis electric module and an auxiliary rail, the X-axis electric module is arranged on the two supports in a crossed mode along the product conveying direction, and the auxiliary rail used in combination with the X-axis electric module is arranged on the supports corresponding to the X-axis electric module. The X-axis electric modules of the product cutting production line conveying mechanism are distributed on the two parallel brackets in a crossed manner, so that the conveying distance is reduced; the product can be carried between different stations simultaneously in the setting of at least one transport subassembly, saves the transport space, improves handling efficiency.

Description

Product cutting production line

Technical Field

The utility model relates to the field of display screen glass production, in particular to a product cutting production line.

Background

With the rapid development of the information industry and the arrival of the 5G era, consumer electronics products are widely applied to clothes and food residents of people as an important means of information propagation, the production of the consumer electronics products becomes a rapidly-developing emerging industry, and the market space is huge and the prospect is wide. The display screen is the most important display tool for consumer electronics, and the quality and efficiency of production affect the price of consumer electronics. The display screen is manufactured by cutting a whole glass into small pieces, wherein the whole glass needs to be cut on two sides and needs to be conveyed among different stations. The existing production equipment has long carrying track, large occupied space and low carrying efficiency, so a product cutting production line is needed, the carrying space is saved, and the carrying efficiency is improved.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problem of low carrying efficiency in the prior art, and provides a product cutting production line with compact structure, high automation degree and high production efficiency.

In order to solve the technical problem, the utility model provides a product cutting production line which comprises a feeding mechanism, a first cutting machine, a translation turnover mechanism, a second cutting machine and a carrying mechanism, wherein the feeding mechanism, the first cutting machine, the translation turnover mechanism and the second cutting machine are sequentially arranged along a product conveying direction, the carrying mechanism comprises at least one carrying assembly for carrying products, the at least one carrying assembly is arranged on two parallel supports arranged along the product conveying direction in a sliding mode through an X-axis electric module and an auxiliary rail, the X-axis electric module is arranged on the two supports in a crossed mode along the product conveying direction, and the auxiliary rail used in combination with the X-axis electric module is arranged on the support opposite to the X-axis electric module.

In one embodiment of the utility model, the feeding mechanism is used for conveying the bins and comprises a belt roller feeding structure, an ion air knife and a paper sucking and separating structure.

In an embodiment of the utility model, the belt roller feeding structure is used for conveying products in the bins to the conveying mechanism for feeding and conveying empty bins to flow out; the ion air knife is arranged on one side of the belt roller feeding structure and used for eliminating static electricity between products and products/separation paper; the paper absorbing and separating structure is used for implementing paper absorbing and separating actions.

In an embodiment of the present invention, the carrying assembly includes a Y-axis carrying platform, a Z-axis carrying platform, and an absorption plane, and is used for adjusting the position of the absorption plane along the X-axis, Y-axis, and Z-axis directions to carry the product; the X-axis electric module and the auxiliary track are connected with a Y-axis transfer platform together, the Y-axis transfer platform is connected with a Z-axis transfer platform, and the Z-axis transfer platform is connected with an adsorption plane.

In an embodiment of the present invention, the carrying assembly further includes a rotating assembly and a material taking and positioning camera, the Z-axis transfer platform is connected to the rotating assembly, and the X-axis electric module, the Y-axis transfer platform, the Z-axis transfer platform and the rotating assembly cooperate to achieve the action of adsorbing the planar positioning product.

In an embodiment of the present invention, the suction plane is an adjustable suction cup, and the adjustable suction cup can adjust a distance between each suction cup.

In an embodiment of the present invention, the adsorption plane is a ceramic adsorption plate, and the ceramic adsorption plate can control the adsorption force by regions.

In an embodiment of the present invention, each of the first cutting machine and the second cutting machine includes a cutting machine body, a camera positioning mechanism, a cutting platform, and a cleaning mechanism; the cutting platform is positioned on the upper surface of the cutting machine body and can move up and down; the camera positioning mechanism is positioned on one side of the cutting machine body and used for identifying marks on products so as to enable the carrying assembly to pick and place the products; the cleaning mechanism is located on the other side of the cutting machine body and used for cleaning the cutting platform.

In an embodiment of the utility model, the translation turnover mechanism comprises a translation mechanism, a material receiving platform and a turnover mechanism; the translation mechanisms are arranged on two sides of the material receiving platform and used for moving the turnover mechanism; the turnover mechanism is slidably mounted on the translation mechanism through a sliding block and used for turning over products.

In one embodiment of the utility model, the material receiving platform comprises a lifting motor set, at least two lifting modules, a lifting limit switch assembly and an adsorption platform, wherein the lifting modules are vertically arranged on opposite surfaces of the material receiving platform, the lifting modules are connected with lifting plates in a sliding manner, and the lifting plates are fixedly connected with the adsorption platform together; the lifting motor set is arranged in a space formed by the material receiving platform and comprises a driving motor and a belt pulley assembly, and the driving end of the driving motor is connected with the driving wheel of each lifting module through the belt pulley assembly and is used for synchronously controlling the lifting of the lifting plate; the lifting motor set, the at least two lifting modules and the lifting limit switch assembly are matched to drive the adsorption platform to move up and down.

Compared with the prior art, the technical scheme of the utility model has the following advantages:

the X-axis electric modules of the product cutting production line conveying mechanism are distributed on the two parallel brackets in a crossed manner, so that the conveying distance is reduced; the product can be carried between different stations simultaneously in the setting of at least one transport subassembly, saves the transport space, improves handling efficiency.

Drawings

FIG. 1 is a schematic view of a product cutting line according to a preferred embodiment of the present invention;

FIG. 2 is a schematic structural diagram of the feeding mechanism in FIG. 1;

FIG. 3 is a schematic structural view of the carrying mechanism in FIG. 1;

FIG. 4 is a schematic structural view of the Y-axis transfer platform shown in FIG. 3;

FIG. 5 is a schematic structural view of the Z-axis transfer platform shown in FIG. 3;

FIG. 6 is a schematic view of the structure of the load handling assembly of FIG. 3;

FIG. 7 is a schematic view of the cut and handle assembly of FIG. 3;

FIG. 8 is a schematic structural view of the blanking handling assembly of FIG. 3;

FIG. 9 is a schematic view of the first/second cutting machine of FIG. 1;

FIG. 10 is a schematic structural view of the translational and overturning mechanism in FIG. 1;

fig. 11 is a schematic structural view of the receiving platform in fig. 8;

in the figure:

1. a feeding mechanism; 11. a belt roller feeding structure; 12. an ion air knife; 13. a paper absorbing and separating structure;

2. a first cutting machine: 21. a cutter body; 22. a camera positioning mechanism; 23. cutting the platform; 24. a cleaning mechanism;

3. a translation turnover mechanism; 31. a translation mechanism;

32. a material receiving platform;

321. a lifting motor set; 3211. a drive motor; 3212. a pulley assembly;

322. a lifting module; 323. an adsorption platform; 324. a lifting plate;

33. a turnover mechanism;

4. a second cutter;

5. a carrying mechanism;

51. a handling assembly; 51a, a loading and carrying assembly; 51b, a cutting and carrying assembly; 51c, a blanking conveying assembly;

511. a Y-axis transfer platform; 5111. a Y-axis fixing plate; 5112. a Y-axis drive module; 5113. a slide rail; 5114. a guide groove;

512. a Z-axis transfer platform; 5121. a Z-axis horizontal fixing plate; 5122. a Z-axis vertical fixing plate; 5123. a Z-axis drive module; 5124. a Z-axis connecting plate; 5125. a chute;

513. an adsorption plane; 5131. an adjustable suction cup; 5132. a ceramic suction plate;

514. a rotating assembly;

515. a material taking and positioning camera;

52. an X-axis motorized module; 53. an auxiliary track; 54. a support; .

Detailed Description

The present invention is further described below in conjunction with the following figures and specific examples so that those skilled in the art may better understand the present invention and practice it, but the examples are not intended to limit the present invention.

Referring to fig. 1, the product cutting production line of this embodiment includes a feeding mechanism 1, a first cutting machine 2, a translational turnover mechanism 3, a second cutting machine 4, and a carrying mechanism 5, which are arranged in sequence along a product conveying direction, where the carrying mechanism 5 includes at least one carrying assembly 51 for carrying a product, and the at least one carrying assembly 51 is slidably disposed on two parallel supports 54 arranged along the product conveying direction through an X-axis electric module 52 and an auxiliary rail 53. When the number of the X-axis electromotive modules 52 is more than one, the X-axis electromotive modules 52 are arranged on two parallel brackets 54 in a crossing manner, and the auxiliary rails 53 used in combination with the X-axis electromotive modules 52 are distributed on the brackets 54 opposite to the X-axis electromotive modules 52; the cross arrangement of the X-axis electric module 52 can reduce the carrying distance of each carrying piece, and the arrangement of at least one carrying assembly 51 can carry products between different stations, so that the carrying space is saved, and the carrying efficiency is improved.

As shown in FIG. 2, the feeding mechanism 1 is used for conveying a bin and comprises a belt roller feeding structure 11, an ion air knife 12 and a paper sucking and separating structure 13.

The belt roller feeding structure 11 is used for conveying products in the material box to the carrying mechanism 5 for feeding and conveying empty material boxes to flow out; the ion air knife 12 is arranged on one side of the belt roller feeding structure 11 and is used for eliminating static electricity between products and products/separation paper; the paper sucking and separating structure 13 is used for performing a paper sucking and separating operation.

As shown in fig. 3, in the present embodiment, three carrying assemblies 51 are provided, three corresponding X-axis motorized modules 52 are provided to intersect on two parallel brackets 54, and an auxiliary rail 53 used in combination with the X-axis motorized modules 52 is provided on the bracket 54 opposite to the X-axis motorized modules 52, that is, two X-axis motorized modules 52 are provided on one bracket 54 and one auxiliary rail 53 is provided therebetween, and two auxiliary rails 53 are provided on the other bracket and one X-axis motorized module 52 is provided therebetween; the carrying assembly 51 comprises a Y-axis carrying platform 511, a Z-axis carrying platform 512 and an adsorption plane 513, wherein the X-axis electric module 52 and the auxiliary rail 53 are connected with the Y-axis carrying platform 511 together, the Y-axis carrying platform 511 is connected with the Z-axis carrying platform 512, the Z-axis carrying platform 512 is connected with the adsorption plane 513, the carrying assembly 51 is adjusted by the X-axis electric module 52 to move back and forth along the X axis to carry products, and the adsorption plane 513 is adjusted by the Y-axis carrying platform 511 and the Z-axis carrying platform 512 to move along the Y axis and the Z axis to accurately pick up the products.

As shown in fig. 3-5, the Y-axis transfer platform 511 includes a Y-axis fixing plate 5111, a Y-axis driving module 5112 and a Y-axis limit switch assembly; the Y-axis fixing plate 5111 is slidably coupled to the X-axis motor module 52 and the auxiliary rail 53, and the Y-axis driving module 5112 is fixed to the Y-axis fixing plate 5111. The bottom of the Y-axis fixing plate 5111 is provided with a sliding rail 5113 along the driving direction of the Y-axis driving module 5112, and a guide groove 5114 along the direction perpendicular to the sliding rail 5113. The guide groove 5114 is used for slidably mounting the Y-axis transfer platform 511 on the bracket 54 so as to be slidable along the X-axis; the slide rail 5113 is used to connect the slide groove 5125 on the Z-axis transfer platform 512, so that the Z-axis transfer platform 512 can slide relative to the Y-axis transfer platform 511.

The Z-axis transfer platform 512 comprises a Z-axis horizontal fixing plate 5121, a Z-axis vertical fixing plate 5122, a Z-axis driving module 5123, a Z-axis connecting plate 5124 and a Z-axis limit switch assembly. The Z-axis horizontal fixing plate 5121 is assembled with the Y-axis driving module 5112 through the sliding groove 5125 disposed on the Y-axis fixing plate 5111, and the Y-axis driving module 5112 is matched with the Y-axis limit switch assembly to drive the Z-axis transfer platform 512 to move along the Y-axis. The Z-axis horizontal fixing plate 5121 is connected with the Z-axis vertical fixing plate 5122, the Z-axis driving module 5123 is fixed on the Z-axis horizontal fixing plate 5121, the Z-axis connecting plate 5124 is assembled and installed with the Z-axis driving module 5123 through a sliding rail and/or a guide rail mechanism arranged on the Z-axis vertical fixing plate 5122, the Z-axis driving module 5123 is matched with the Z-axis limit switch assembly to drive the Z-axis connecting plate 5124 to move along the Z axis, and a pressure gauge is further arranged on the Z-axis connecting plate.

As shown in fig. 3-6, when the carrying assembly 51 reciprocates between the loading mechanism 1 and the first cutting machine 2, the carrying assembly 51a is a loading carrying assembly 51a, the loading carrying assembly 51a further includes a rotating assembly 514 and a loading positioning camera 515, the Z-axis transfer platform 512 is connected to the adsorption plane 513 through the rotating assembly 514, the loading positioning camera 515 is disposed on the adsorption plane 513, the rotating assembly 514 is preferably a rotary DD motor, the rotary DD motor can adjust an offset angle of the adsorption plane 513 relative to a center of a product, an image on the product extracted by the loading positioning camera 515 captures a mark on the product to be processed through a software algorithm, and sends a control instruction directly or through a control device, so as to guide the X-axis electric module 52, the Y-axis transfer platform 511, and the Z-axis transfer platform 512 to cooperate with the rotating assembly 514 to realize an action of the product picked up by the adsorption plane 513.

As shown in fig. 3-5 and 7, when the carrying assembly 51 reciprocates between the first cutting machine 2 and the second cutting machine 4, the cutting and carrying assembly 51b further includes a rotating assembly 514, the rotating assembly 514 is preferably a rotary DD motor, the rotary DD motor can adjust the offset angle of the adsorption plane 513 relative to the center of the product, one side of each of the first cutting machine 2 and the second cutting machine 4 is provided with a camera positioning mechanism 22, the camera positioning mechanism 22 extracts an image on the product, captures a mark on the product to be processed through a software algorithm, and sends a control command directly or through a control device, so as to guide the X-axis electric module 52, the Y-axis transfer platform 511, and the Z-axis transfer platform 512 to cooperate with the rotating assembly 514 to realize the action of picking up the product by the adsorption plane 513.

As shown in fig. 3-5 and 8, when the conveying assembly 51 reciprocates between the second cutting machine 4 and the next station, the conveying assembly 51c is a blanking conveying assembly, the Z-axis connecting plate 5124 of the blanking conveying assembly 51c is a suction plane 513, the camera positioning mechanism 22 extracts an image on a product, captures a mark on the product to be processed through a software algorithm, and sends a control instruction directly or through a control device, so as to guide the X-axis electric module 52 and the Y-axis transfer platform 511 to cooperate with the Z-axis transfer platform 512 to realize the action of picking up the product by the suction plane 513.

As shown in fig. 3-8, in the present embodiment, the suction plane 513 is an adjustable suction cup 5131, and the adjustable suction cup 5131 can adjust the distance between each suction cup by several cylinders to adapt to products with different sizes.

In other embodiments, the adsorption plane may also be a ceramic adsorption plate 5132, the surface of the ceramic adsorption plate 5132 is smooth and flat, the ceramic material has high hardness, good wear resistance and good oxidation resistance, and is not easy to scratch the product, and the ceramic adsorption plate 5132 can control the adsorption force in different areas, so that the products of different sizes can still be completely adsorbed after being cut.

As shown in fig. 9, each of the first cutter 2 and the second cutter 4 includes a cutter body 21, a camera positioning mechanism 22, a cutting platform 23, and a cleaning mechanism 24; the cutting platform 23 is positioned on the upper surface of the cutter body 21 and can move up and down; the camera positioning mechanism 22 is located at one side of the cutting machine body 21 and used for identifying marks on products so that the carrying assembly can take and place the products; the cleaning mechanism 24 is located on the other side of the cutter body 21 for cleaning the cutting platform 23.

As shown in fig. 10, the translation and turnover mechanism 3 includes a translation mechanism 31, a material receiving platform 32 and a turnover mechanism 33; the translation mechanisms 31 are arranged on two sides of the material receiving platform 32 and used for moving the turnover mechanism 33; turnover mechanism 33 passes through slider slidable mounting on translation mechanism 31 for the product overturns, and turnover platform of turnover mechanism 33 can adsorb the product by the subregion.

As shown in fig. 11, the material receiving platform 32 includes a lifting motor set 321, at least two lifting modules 322, a lifting limit switch assembly and an adsorption platform 323, the lifting modules 322 are vertically disposed on the opposite surface of the material receiving platform 32, the lifting modules 322 are slidably connected with a lifting plate 324, the lifting plates 324 are jointly and fixedly connected with the adsorption platform 323, and the adsorption platform 323 can adsorb products in different areas; the lifting motor group 321 is arranged in a space formed by the material receiving platform and comprises a driving motor 3211 and a belt pulley assembly 3212, wherein the driving end of the driving motor 3211 is connected with the driving wheel of each lifting module 322 through the belt pulley assembly 3212 and is used for synchronously controlling the lifting of the lifting plate 324; the lifting motor set 321, at least two lifting modules 322 and the lifting limit switch component are matched to drive the adsorption platform 323 to move up and down.

To sum up, the transport subassembly of this embodiment sets up to three, can be simultaneously transport the product between different stations, saves transport space, improves work efficiency.

The optional workflow of this embodiment is as follows:

the feeding mechanism 1 conveys the bin to the lower part of a feeding and conveying assembly 51a of the conveying mechanism 5, the feeding and conveying assembly 51a positions the product in the bin through a material taking and positioning camera 515, and guides the X-axis electric module 52, the Y-axis transfer platform 511, the Z-axis transfer platform 512 to be matched with the rotating assembly 514 so as to realize the action of picking up the product by the adsorption plane 513; after the product is picked up, the paper absorbing and separating structure 13 transfers the paper separating between the products to an empty bin; in the process of picking up the product and transferring the paper, the ion wind knife 12 continuously provides negative ion wind to eliminate static ions and prevent the product from being damaged by the ions;

after picking up a product, the loading and carrying assembly 51a moves to the first cutting machine 2 under the drive of the X-axis electric module 52, is positioned by the camera positioning mechanism 22 of the first cutting machine 2, guides the X-axis electric module 52, the Y-axis transfer platform 511, the Z-axis transfer platform 512 and the rotating assembly 514 to be matched to place the product on the cutting platform 23 of the first cutting machine 2, and returns to the initial position to pick up the next product;

after the first cutting machine 2 finishes cutting one surface, the cutting and carrying assembly 51b positions and guides the X-axis electric module 52, the Y-axis transfer platform 511, the Z-axis transfer platform 512 and the rotating assembly 514 through the camera positioning mechanism 22 of the first cutting machine 2 to cooperate to realize the action that the adsorption plane 513 picks up the product, and carries the product to the turnover mechanism 33; meanwhile, the cleaning mechanism 24 of the first cutting machine 2 cleans the cutting platform 23 of the residual material generated by cutting the product;

the turnover mechanism 33 is driven by the translation mechanism 31 to move to the rear, the turnover mechanism 33 is driven by the translation mechanism 31 to move to the upper side of the material receiving platform 32 after turning over the product for 180 degrees, the adsorption platform 323 of the material receiving platform 32 is driven by the lifting motor set 321 to ascend to be in contact with the turnover platform of the turnover mechanism 33, the turnover platform breaks vacuum, the turnover mechanism 33 places the product on the adsorption platform 323, and the turnover mechanism 33 moves backwards;

the cutting and carrying assembly 51b is matched with the X-axis electric module 52, the Y-axis transfer platform 511, the Z-axis transfer platform 512 and the rotating assembly 514 to realize the action of picking up the product by the adsorption plane 513, and carry the product to the other cutting surface of the second cutting machine 4, and the camera positioning mechanism 22 of the second cutting machine 2 positions and guides the cutting and carrying assembly 51b to place the product on the cutting platform 23 of the second cutting machine 4; the cutting and carrying assembly 51b returns to the upper part of the first cutting machine 2 to pick up the next product;

after the second cutting machine 4 finishes cutting the other surface, the blanking carrying assembly 51c positions and guides the X-axis electric module 52, the Y-axis transfer platform 511 and the Z-axis transfer platform 512 to cooperate with each other through the camera positioning mechanism 22 of the second cutting machine to realize the action that the adsorption plane 513 picks up the product, and carries the product to the next station; at the same time, the cleaning mechanism 24 of the second cutting machine 4 cleans the cutting platform 23 of the residue material generated by cutting the other side of the product.

The feeding and carrying assembly 51a carries the product in a reciprocating motion between the feeding mechanism 1 and the first cutting machine 2; the cutting and carrying assembly 51b carries the product by reciprocating between the first cutting machine 2 and the second cutting machine 4; the blanking conveying assembly 51c reciprocates between the second cutting machine 4 and the next station to convey products; a plurality of groups of carrying assemblies carry simultaneously, so that the working efficiency is improved; and the feeding mechanism 1 sends out the empty work bin until the work bin carries the products.

The above embodiments are merely preferred embodiments for fully illustrating the present invention, and the scope of the present invention is not limited thereto. The equivalent substitution or change made by the technical personnel in the technical field on the basis of the utility model is all within the protection scope of the utility model. The protection scope of the utility model is subject to the claims.

Claims (10)

1. The utility model provides a product cutting production line, includes feed mechanism, first cutting machine, translation tilting mechanism, the second cutting machine that arranges in proper order along product direction of delivery, its characterized in that still includes transport mechanism, transport mechanism includes at least one transport subassembly that is used for carrying the product, and at least one transport subassembly passes through the electronic module of X axle and supplementary track slides and sets up on two supports that parallel that set up along product direction of delivery, the electronic module of X axle alternately sets up on two supports along product direction of delivery, sets up on the support corresponding with the electronic module of X axle with the supplementary track that the electronic module combination of X axle was used.

2. The product cutting line as set forth in claim 1, wherein the feeding mechanism is for a delivery bin, including a belt roller feeding structure, an ion wind knife, and a suction and separation paper structure.

3. The product cutting line as set forth in claim 2, characterized in that the belt roller loading structure is used for conveying the products in the bins to the handling mechanism for loading and conveying the empty bins to flow out; the ion air knife is arranged on one side of the belt roller feeding structure and used for eliminating static electricity between products and products/separation paper; the paper absorbing and separating structure is used for implementing paper absorbing and separating actions.

4. The product cutting production line of claim 1, wherein the carrying assembly comprises a Y-axis carrying platform, a Z-axis carrying platform and an adsorption plane, and is used for adjusting the position of the adsorption plane along the X-axis direction, the Y-axis direction and the Z-axis direction to carry the products; the X-axis electric module and the auxiliary track are connected with a Y-axis transfer platform together, the Y-axis transfer platform is connected with a Z-axis transfer platform, and the Z-axis transfer platform is connected with an adsorption plane.

5. The product cutting line as set forth in claim 4, wherein the carrying assembly further comprises a rotating assembly and a material taking and positioning camera, the Z-axis transfer platform is connected with the adsorption plane through the rotating assembly, and the X-axis electric module, the Y-axis transfer platform, the Z-axis transfer platform and the rotating assembly cooperate to realize the action of positioning the product by the adsorption plane.

6. The product cutting line according to claim 4 or 5, characterized in that said suction plane is an adjustable suction cup, said adjustable suction cup being able to adjust the distance between each suction cup.

7. The product cutting line according to claim 4 or 5, wherein the adsorption plane is a ceramic adsorption plate capable of controlling adsorption force by regions.

8. The product cutting line of claim 1, wherein the first and second cutting machines each comprise a cutting machine body, a camera positioning mechanism, a cutting platform, and a cleaning mechanism; the cutting platform is positioned on the upper surface of the cutting machine body and can move up and down; the camera positioning mechanism is positioned on one side of the cutting machine body and used for identifying marks on products so as to enable the carrying assembly to pick and place the products; the cleaning mechanism is located on the other side of the cutting machine body and used for cleaning the cutting platform.

9. The product cutting production line of claim 1, wherein the translation turnover mechanism comprises a translation mechanism, a material receiving platform and a turnover mechanism; the translation mechanisms are arranged on two sides of the material receiving platform and used for moving the turnover mechanism; the turnover mechanism is slidably mounted on the translation mechanism through a sliding block and used for turning over products.

10. The product cutting production line of claim 9, wherein the material receiving platform comprises a lifting motor set, at least two lifting modules, a lifting limit switch assembly and an adsorption platform, the lifting modules are vertically arranged on opposite surfaces of the material receiving platform, the lifting modules are connected with lifting plates in a sliding manner, and the lifting plates are fixedly connected with the adsorption platform together; the lifting motor set is arranged in a space formed by the material receiving platform and comprises a driving motor and a belt pulley assembly, and the driving end of the driving motor is connected with the driving wheel of each lifting module through the belt pulley assembly and is used for synchronously controlling the lifting of the lifting plate; the lifting motor set, the at least two lifting modules and the lifting limit switch assembly are matched to drive the adsorption platform to move up and down.

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